The role of polyfusomes in generating branched chains of cystocytes during Drosophila oogenesis

Three-dimensional models were constructed utilizing the information gained from electron micrographs of serial sections of two clones of cystocytes undergoing their terminal divisions. In each clone a polyfusome connected all eight cystocytes together. Each of the spindles was oriented so that one pole touched the polyfusomes, while the other pointed away from it. This positioning of spindles ensures that one cell of each dividing pair retains all previously formed canals, while the other receives none. The two cells that eventually come to contain the maximum number of canals and fusomal material are the ones that differentiate as pro-oocytes, while the others become nurse cells. The orientation of each spindle suggests that the polyfusome formed at one division determines the placement of the cytoskeletal fibers that anchor the spindles formed at the next division. There is a centripetal gathering together of new canals following each cycle of cystocyte division, which is thought to result from the subsequent contraction of the polyfusomal system. Females homozygous for the otu1 mutation are characterized by ovarian tumors, which result when germarial cystocytes undergo supernumerary divisions and fail to differentiate into either nurse cells or oocytes. An analysis of electron micrographs taken of serially sectioned, mutant germaria showed that most germ cells were single or belonged to clusters of two or three interconnected cells. Therefore otu1 cystocytes are unable to undergo a sustained series of arrested cleavages. These cystocytes contain fusomal material that shows ultrastructural differences from normal polyfusomes. We conclude: 1) that a normal polyfusomal system is a necessary prerequisite for the production of a branched chain of cystocytes and for their subsequent differentiation into pro-oocytes and nurse cells; and 2) that a product encoded by the otu+ gene is essential for the construction of a functional polyfusome.     

Structural organization of ovarian follicle cells in the cotton bug (Dysdercus intermedius) and the honeybee (Apis mellifera)

Summary The somatic epithelia of Dysdercus and Apis follicles were analyzed by electron microscopy, and the patterns of F-actin and microtubules were studied by fluorescence microscopy. The epithelia in both species differ considerably in shape and in the organization of the cytoskeleton. During previtellogenic stages, the epithelium consists of columnar-shaped cells with small (Dysdercus) or no (Apis) lateral intercellular spaces. During vitellogenesis, the follicle cells round up; the intercellular spaces increase in size in Dysdercus follicles, whereas in Apis follicles they remain small. Along the basal surface of the follicle cells, there are conspicuous parallel bundles of microfilaments perpendicular to the anteroposterior axis of the follicles. In the honeybee, these microfilament bundles are present in long filopodia, most of which are embedded in thickenings of the basement membrane and extend over the surfaces of neighbouring cells. In the cotton bug, the basal surface of the follicle cells is thrown into parallel folds. The microfilament bundles are located just underneath the cell membrane where the folds contact the basement membrane. In the polar regions of the Dysdercus follicle, the epithelial cells become flat and adhere to each other without forming intercellular spaces. The basement membrane is particularly thick in the polar areas; this has also been observed in Apis follicles around the intercellular bridge connecting oocyte and nurse cells.     

Oocytes develop from interconnected cystocytes in the panoistic ovary of Nemoura sp. (Pictet) (Plecoptera : Nemouridae)

The 2 ovaries of Nemoura sp. (Plecoptera : Nemouridae) are comb-like and house about 60–70 ovarioles each. By ultrathin serial sections through a whole ovariole of a last-larval instar, we gathered information on its ultrastructure and 3-dimensional architecture. The germarial region contains several clusters of interconnected oogonia or oocytes. The intercellular bridges (ring canals) are filled with fusomes. Most of the fusomes assemble to polyfusomes and some of the intercellular bridges move together and their cells assemble to rosettes. Results indicate that existence of polyfusomes is not sufficient for rosette formation. The oogonia or oocytes of each cluster develop synchronously. Oocytes detach from clusters next to intercellular bridges. A transdetermination of oogonia to nurse cells does not occur. Thus, the stone flies remain true panoists.     

Structure and development of the telotrophic ovariole in ensign scale insects (Hemiptera, Coccomorpha: Ortheziidae)

The paired ovaries of young larva of the 3rd instar of Orthezia urticae are filled with numerous germ cell clusters that can be regarded as ovariole anlagen. Germ cells (cystocytes) belonging to one cluster form a rosette, in the centre of which a polyfusome occurs. Staining with rhodamine-phalloidin has revealed that polyfusomes contain numerous microfilaments. The number of cystocytes per cluster is not stable and varies considerably. The ovaries of older larva become elongated with numerous young ovarioles protruding into the body cavity. The ovarioles are not subdivided into the tropharium and vitellarium. In this stage germ cells differentiate into oocytes and trophocytes (nurse cells). The ovaries of adult females are composed of about 20 (Newsteadia floccosa) or 30 (O. urticae) ovarioles. Their trophic chambers contain trophocytes and arrested oocytes. In the vitellarium, at the given moment, only one oocyte develops. It has been observed that after maturation of the first egg the arrested oocytes may develop.     

Germ cells cluster organization in polytrophic ovaries of neuroptera

Histological and ultrastructural analysis of polytrophic ovary structure in Neuroptera revealed an unusual organization of their germ cell clusters. In all species under study (representing 5 families), clusters with variable and unfixed numbers of cystocytes are formed. Moreover, spatial organization of cystocyte connections within the cluster is linear rather than typically branched; only a few branching sites being observed. The oocyte is located in the central, always linear, part of the cluster and therefore is directly connected via intercellular bridges with only two nurse cells. It is postulated here that the linear character of germ cell clusters in Neuroptera may result from asynchrony of cystocyte divisions. Mechanisms of germ cell cluster formation and differentiation are discussed.     

Structure and development of ovaries in the weevil,Anthonomus pomorum (Coleoptera,Polyphaga). II. Germ cells of the trophic chamber

The analysis of the germ cell cluster formation in Anthonomus pomorum (Coleoptera, Polyphaga, Curculionidae) has revealed that both linear and branched clones of cystocytes occur in the pupa stage. In the branched clones a poorly developed polyfusome is formed and cystocytes with maximally 3 intercellular bridges were found. In the linear clones the polyfusomes are absent. Further divisions of cystocytes produce exclusively linearly arranged cells. Just after metamorphosis (Imago-A stage), the process of the germ cell membrane reduction starts. Only 2 groups of cells retain cell membranes: i.e the most anteriorly localized group of cystocytes and the posteriorly located presumptive oocytes. The former cells divide mitotically during the summer. As a result an anterior-posterior gradient of the syncytialization process arises in the Imago-B stage (females preparing for hibernation). In the sexually mature females (Imago-C) the trophic chamber consists of a huge syncytial area with numerous nurse cell nuclei embedded in a common cytoplasm, and posteriorly located young oocytes surrounded by prefollicular cells. In the light of recent hypothesis concerning the germ cell cluster formation and telotrophy anagenesis in Polyphaga the significance of the presented results is discussed.     

Formation of germ-line cysts with a central cytoplasmic core is accompanied by specific orientation of mitotic spindles and partitioning of existing intercellular bridges

Animal germ cells tend to form clonal groups known as clusters or cysts. Germ cells within the cyst (cystocytes) are interconnected by intercellular bridges and thus constitute a syncytium. Our knowledge of the mechanisms that control the formation of germ-cell clusters comes from extensive studies carried on model organisms (Drosophila, Xenopus). Germ-cell clusters have also been described in worms (annelids, flat worms and nematodes), although their architecture differs significantly from that known in arthropods or vertebrates. Their peculiar feature is the presence of a central anucleate cytoplasmic core (cytophore, rachis) around which the cystocytes are clustered. Each cystocyte in such a cluster always has one intercellular bridge connecting it to the central cytoplasmic core. The way that such clusters are formed has remained a riddle for decades. By means of light, fluorescence and electron microscopy, we have analysed the formation and architecture of cystocyte clusters during early stages of spermatogenesis and oogenesis in a few species belonging to clitellate (oligochaetous) annelids. Our data indicate that the appearance of germ cells connected via a central cytophore is accompanied by a specific orientation of the mitotic spindles during cystocyte divisions. Spindle long axes are always oriented tangentially to the surface of the cytophore. In consequence, cystocytes divide perpendicularly to the plane of the existing intercellular bridge. Towards the final stages of cytokinesis, the contractile ring of the cleavage furrow merges with the rim of the intercellular bridge that connects the dividing cystocyte with the cytophore and forces partition of the existing bridge into two new bridges. This work was supported by the following research grants: 2P04C004 28 from the Ministry of Science and Informatization (to P. Świątek and J. Klag) and DS/1018/IZ/2007 (to J. Kubrakiewicz).     

The microfilament pattern in the somatic follicle cells of mid-vitellogenic ovarian follicles of Drosophila

The microfilament pattern in the somatic follicle cells of mid-vitellogenic stage 9 to 11 follicles of Drosophila was analyzed by staining F-actin with fluorescence-labeled phalloidin. During the analyzed stages of oogenesis, the follicular epithelium differentiates morphologically and functionally. These changes are also reflected at the organization of the microfilaments. At stage 10, they show no preferred orientation in the very thin follicle cells covering the nurse cells. In contrast, the microfilaments in the basal part of the columnar follicle cells covering the oocyte become organized in parallel bundles oriented perpendicular to the long axis of the follicle. During stages 10B/11 this organization is maintained at the nurse cell/oocyte border but becomes more sloppy towards the posterior pole of the follicle. The basal part of the follicle cells containing the microfilament bundles adheres so tightly to the basement membrane that this acellular layer cannot be separated mechanically from the epithelium. Indirect evidence from inhibition studies with cytochalasins and the effects of collagenase or pronase E added to the culture medium suggest that the microfilament bundles may promote increased adhesiveness of the follicle cells to the basement membrane. The possible functional implications of the microfilaments and their orientation are discussed.     

The origin and early differentiation of the egg chamber of Drosophila melanogaster

The egg chamber of Drosophila melanogaster consists of 16 interconnected cells surrounded by a monolayer of follicle cells. Each 16 cell cluster (from which the oocyte and 15 nurse cells differentiate) arises within the germarial region of an ovariole. To study the ultrastructure of the early stages in the formation and differentiation of egg chambers, a three dimensional reconstruction was made from serial thin sections through a germarium from a 24-hour old, virgin female. The germarium was found to be subdivided into three regions: (1) The mitotically active area where clusters of 16 cells originate from a series of cystocyte divisions, (2) the region where these cells interact with mesodermal cells, and (3) the region where the germarial cyst is transformed into the first egg chamber in the vitellarium. Since cystocytes were found to decrease in size with each division, the possibility exists that cell size may determine when the divisions cease. Models are presented which mimic with varying degrees of success the developmental changes the germarial cells undergo with time. Hypothesis are developed to explain why stem line oogonia are restricted to the anterior portion of the germarium, why mesodermal cells first interact with cystocytes in region 2, and why the oocyte is oriented posteriorly. The nuclear differentiations of the component cells of the chamber are described and correlated with observed differences in radiosensitivity. Symbionts were observed in the germaria of several strains of Drosophila, and the bearing of these findings upon nutritional studies is discussed.     

Further studies on the ring canal system of the ovarian cystocytes of Drosophila melanogaster

Summary An ultrastructural study was made of the ring canal system which connects the sister ovarian cystocytes that arise in the germaria of wild type Drosophila melanogaster females. It was discovered that during an oogonial mitosis both chromosomes and spindle are enclosed by a multilayered, perforated membrane system derived (at least in part) from the nuclear envelope. The cytokinesis of stem line oogonia takes place through the formation of a cleavage furrow. A second method of formation of plasma membrane is found in the case of cystocytes. It involves the production along the plane of division of a plaque of interconnected vesicles and tubules and later the coalescence of nearby tubules to form continuous sheets of membrane which segregate the cytoplasms of the sister cells. However, these remain connected by a canal which is enclosed by a ring-shaped rim that is completed prior to the plasma membrane to which the rim is subsequently attached. It is postulated that the rim represents a transformed midbody. As development proceeds the canal becomes wider, its rim becomes thicker, and the inner circumference of the rim becomes coated with a thick deposit having different cytochemical properties than the rim itself. Cystocyte divisions produce sister cells which differ in that one receives all previously formed canals; the other none. In the case of the last division (and perhaps in earlier ones as well) the sister cell receiving all previously formed canals also receives more cytoplasm than its sister. As the cells of the cluster grow, the canals remain close together. This finding suggests that when new plasma membrane is synthesized, it is added in areas remote from the canals. An investigation of the positioning in three dimensions of the fifteen canals of a newly formed, 16 cellcluster suggests that the spindles produced at one division are never parallel to those formed at the subsequent division. This continual shifting of the axes of the spindles at consecutive divisions presumably results in the branching chains of cells which characterize a cystocyte cluster. The possession of a unique pattern of cortical structures by two cystocytes is accompanied by the nuclear synthesis of synaptonemal complexes. The other fourteen cystocytes differentiate into nurse cells. In the most posterior portion of the germarium one of the two potential oocytes switches to the nurse cell developmental pathway. This switched off oocyte and the definitive oocyte grow at rates which differ greatly and are correlated to the amount of contact between their surfaces and certain follicle cells. As development proceeds centrioles accumulate in the oocyte, and most of these are thought to have been carried from the nurse cells into the oocyte in the nutrient stream.The authors are grateful to Richard Z. Belch and James E. Bradof for their conscientious assistance and to E. John Pfiffner for preparation of the inked drawings and construction of the Polyform models. This research was supported by the National Science Foundation grant GB7457.     

Organization of the cytoskeleton in the coenocytic algaVaucheria longicaulis var.macounii: an experimental study

Summary The organization of the cytoskeleton of vegetative filaments ofVaucheria longicaulis Hoppaugh var.macounii Blum is investigated by fluorescence microscopy using monoclonal anti -tubulin antibodies and fluorescein (FITC)-labelled phalloidin. Confocal laser scanning microscopy observations give further information on the distribution of the cytoskeletal elements. Phalloidin labelling reveals F-actin bundles in the cortical cytoplasm of both fixed and unfixed vegetative filaments of this alga. In addition a more diffuse fluorescent component, seen at higher magnification to be made up of thinner F-actin bundles, can also be detected in unfixed cells. The distribution of the F-actin bundles resemble that of filamentous structures observed with differential interference contrast (DIC) microscopy in living cells. These structures seem to correspond to the microtubule associated reticulum (MAR) described in literature and overall the evidence suggests that actin and MAR elements are co-distributed. F-actin bundles are always found in association with focal masses (foci) of phalloidin-positive material. Foci are also observed by DIC microscopy associated with the cytoplasmic filamentous structures in living cells.Depolymerization of F-actin with cytochalasin D and the subsequent repolymerization that occurs on transfer ofVaucheria vegetative filaments to cytochalasin-free medium suggest that these foci are involved in the organization of the F-actin array. Immunofluorescence for -tubulin reveals microtubule bundles that are shorter in length and straighter in configuration than microfilament bundles. Microtubule bundles are associated with spot-like focal structures that, in many instances, show a close relationship with respect to nuclei. Oryzalin and cold temperature cause the depolymerization of the microtubule bundles and suggest, in conjunction with repolymerization studies, that these fluorescent spots associated with the ends of the microtubule bundles are involved in their organization; hence, they represent microtubule organizing centres or MTOCs. The importance of both microfilament and microtubule bundle focal regions is discussed with respect to the apical growth exhibited by the vegetative filaments of this alga.     

Ultrastructure and cluster formation in ovaries of bark lice,Peripsocus phaeopterus (Stephens) and Stenopsocus stigmaticus (Imhof and Labram) (Insecta : Psocoptera)

Ultrastructure and previtellogenic growth of ovaries of Peripsocus phaeopterus (Stephens) and Stenopsocus stigmaticus (Imhof and Labram) (Insecta : Psocoptera) are described. The germ cell cluster formation was analyzed in an ovariole of a nymph using ultrathin serial sectioning. Fifteen germ cell clusters were found; 13 contained 4 cystocytes each, while 2 clusters, situated in the very tip, were composed of 2 cystocytes each. A fully developed cluster rises by 2 synchronized mitotic divisions, each followed by incomplete cytokinesis. Microtubules derived from the preceding mitoses form a transient midbody within the intercellular bridge. Later on, a fusome fills each bridge, while at fusomal rims parallel oriented microtubules are tightly associated. Some of these microtubules stretch to cell membranes nearby. The fusomes fuse into a polyfusome and a rosette is thus formed by which all intercellular bridges are drawn together. All cystocytes enter the prophase of meiosis up to pachynema. One of the 2 inner cells continues meiosis and develops as an oocyte, whereas all others transform into nurse cells. After rosette formation, the polyfusome-associated microtubules vanish and some time later, when the nurse cell-oocyte differentiation becomes apparent, the polyfusome itself becomes destroyed. The intercellular bridge, joining the first nurse cell with the 3rd moves away from the other 2. During previtellogenesis, 5 phases can be distinguished, 2 of which are interpreted as logarithmical growth phases with different slopes. The whole set of characters elaborated here for the polytrophic meroistic ovary of psocopterans is fully consistent with the characters of polytrophic meroistic ovaries of Holometabola, indicating a monophyletic origin.     

F-actin rings are associated with the ring canals of the Drosophila egg chamber

Staining of Drosophila egg chambers with rhodaminyl-lysine-phallotoxin (RLP), a specific stain for F-actin, has demonstrated the presence of dense F-actin rings associated with the inner surfaces of the ring canals. They were first observed in the distal part of the germarium where rings of four different size classes were found, differing in diameter by up to twofold. The ring sizes are considered to correspond to the ring canals formed at each of four successive incomplete cleavages. During the growth of the egg chamber the actin rings were found to increase in diameter from less than 1 micron to approx. 10 micron. Concomitantly a secondary outer ring of more diffuse material is built up in association with the cell membranes. A well developed array of microfilament bundles was also associated with the nurse cell plasmalemma. In stages where the transfer of the bulk of the nurse cell cytoplasm into the oocyte was occurring the rings came closer together in a central area. In late stage chambers the F-actin rings and the microfilament bundles appeared to be incorporated into large irregular masses of actin, which subsequently disappeared as the mature oocyte formed. The F-actin rings are suggested to act as mechanical strengthening elements for the canal plasmalemma, whilst cytoplasmic transport occurs through the ring canals.     

The linear clusters of oogonial cells in the development of telotrophic ovarioles in polyphageColeoptera

Summary During the premetamorphic development of coleopteran telotrophic ovaries the culsters of sister oogonial cells, in which the differentiation of nurse cells and oocytes occurs, are arranged in linear chains. This results from a series of mitoses with the consistent orientation of the spindle parallel to the long axis of the ovariole. As a result of incomplete cytokinesis, the oogonial cells in each sibling cluster are linked to each other by intercellular bridges occupied by fusomes. As a rule, at each cluster division the basal cell (i.e. the oocyte progenitor) starts to divide first. From this cell a wave of mitoses spreads toward the anterior end of the cluster, resulting in a mitotic gradient. It is suggested that the failure of the fusomes in adjacent cells to fuse into one continuous fusome (i.e. polyfusome) allows the spindles to orientate with their long axes parallel to the long axis of the sibling cluster. This would explain why the oogonial divisions in coleopteran telotrophic ovaries generate linear chains of cells rather than the cyst-like arrangement which is typical for polytrophic sibling clusters. Dividing sibling clusters within ovarioles are arranged in bundles. The presence of intercellular bridges between sibling clusters seems to be the underlying cause of this nonrandom distribution of the mitotically active clusters. The transverse bridges have been found to occur between the basal cells as well as between the cells located more anteriorly in adjacent sibling clusters. The transverse bridges are filled with typical fusomes, which in more anterior parts of sibling clusters may fuse with the fusomes of adjacent sister oogonial cells into polyfusomes. The transverse bridges between the basal cells are incorporated in the oocytes. The pattern of sibling cluster formation described in this paper apparently occurs widespread in polyphagous Coleoptera, since it has been found in three relatively distantly related families.     

Ultrastructural observations on the oogenesis of Triops cancriformis (Crustacea,Notostraca)

Summary Each ovarian follicle of Triops cancriformis is four-celled; these cells (one oocyte and three nurse cells) are interconnected by cytoplasmic bridges. In the course of differentiation, the nurse cells are early recognizable; they increase in size more than the oocyte and their nuclei contain many nucleoli. For the first time in Arthropoda, yolk globules are reported to be present in nurse cell cytoplasm; these globules arise from the smooth endoplasmic reticulum. The functional significance of the intercellular bridges and the trophic role of the nurse cells are discussed.The authors are grateful to Dr. Bruno Sabelli for his support and to Mr. Francesco Monte for his technical assistance     

Microtubule organization in the sperm ofTradescantia virginiana

Summary Microtubules were visualized in the sperm ofTradescantia virginiana pollen tubes grownin vitro and processed for antitubulin immunocytochemistry. The sperm contain thick microtubule bundles from which emerge numerous branches of various dimensions disposed longitudinally and helically along the cell axis. Sperm are usually spindle or cigar-shaped, but cells of various sizes and shapes can be found. All contain microtubule arrays. No F-actin was detected in sperm using rhodamine-phalloidin staining. Sperm microtubules are discussed in terms of their potential roles in cell shaping and motility and their origin during generative cell division.Abbreviations DAPI 4,6-diamidino-2-phenylindole - IgG immunoglobulin G - M+W Mascarenhas and Walker medium - Mf microfilament - Mt microtubule - PBA phosphate-buffered saline     

The somatic envelopes around the germ-line cells of polytrophic insect follicles: Structural and functional aspects

The polytrophic ovarioles of three insect species, the fruit fly Drosophila melanogaster, the fungus gnat Bradysia tritici, and the honeybee Apis mellifera, were compared morphologically and with respect to the cytological organization of the peripheral somatic layers. Staining with rhodaminyl-phalloidin revealed differences in the organization of the muscle strands of the epithelial sheath and the microfilament pattern in the basal part of the follicular epithelium (mid-vitellogenic stages). Also, the size of the intercellular space between the follicle cells differed considerably in the three analyzed species. The basement membrane of Drosophila and Bradysia follicles was partially digested using purified collagenase. The observed morphological changes indicated that in both species the basement membrane of the follicular epithelium plays an important role in shaping the follicles. The possible functional significance of the species-specific structural differences is discussed.     

Early oogenesis in the short-tailed fruit bat Carollia perspicillata: transient germ cell cysts and noncanonical intercellular bridges

The ovaries of early embryos (40 days post coitum/p.c.) of the bat Carollia perspicillata contain numerous germ-line cysts, which are composed of 10 to 12 sister germ cells (cystocytes). Variability in the number of cystocytes within the cyst and between the cysts (defying the Giardina rule) indicates that the mitotic divisions of the cystoblast are asynchronous in this bat species. Serial section analysis showed that the cystocytes are interconnected via intercellular bridges that are atypical, strongly elongated, short-lived, and rich in microtubule bundles and microfilaments. During slightly later stages of embryonic development (44-46 days p.c.), somatic cells penetrate the cyst, and their cytoplasmic projections separate individual oocytes. Separated oocytes surrounded by a single layer of somatic cells constitute the primordial ovarian follicles. The oocytes of C. perspicillata are similar to mouse oocytes and are asymmetric. In both species, this asymmetry is clearly recognizable in the localization of the Golgi complexes. The presence of germ-line cysts and intercellular bridges (although noncanonical) in the fetal ovaries of C. perspicillata suggest that the formation of germ-line cysts is an evolutionarily conserved phase in the development of the female gametes in a substantial part of the animal kingdom.     

Germ cell cluster formation and ovariole structure in viviparous and oviparous generations of the aphid Stomaphis quercus

The developing ovaries of S. quercus contain a limited number of oogonial cells which undergo a series of incomplete mitotic divisions resulting in the formation of clusters of cystocytes. Ovaries of viviparous generations contain 6 to 9 clusters, containing 32 cystocytes each, whereas ovaries of oviparous generations contain 5 clusters containing 45-60 cystocytes. During further development, clusters become surrounded by a single layer of follicular cells, and within each cluster the cystocytes differentiate into oocytes and trophocytes (nurse cells). Concurrently, cysts transform into ovarioles. The anterior part of the ovariole containing the trophocytes becomes the tropharium, whereas its posterior part containing oocytes transforms into the vitellarium. The vitellaria of viviparous females are composed of one or two oocytes, which develop until previtellogenesis. The nuclei of previtellogenic oocytes enter cycles of mitotic divisions which lead to the formation of the embryo. Ovarioles of oviparous females contain a single oocyte which develops through three stages: previtellogenesis, vitellogenesis and choriogenesis. The ovaries are accompanied by large cells termed bacteriocytes which harbor endosymbiotic microorganisms.